Water cooled panel

ABSTRACT

A water cooled panel is comprised by a continuous coil having a plurality of straight pipe sections and “U” shaped 180° elbow sections that are integral part of the pipe.

BACKGROUND OF THE INVENTION

A. Field of the Invention

The present invention is related to water cooled panels for electric arc furnaces and more particularly to a water cooled panel having a tubular design comprised by a continuous coil formed by a thick wall pipe in which the 90° & 180° elbows are integral to the tube.

B. Description of the Related Invention

Temperatures higher than 2300° F. are generated inside the electric arc furnaces, therefore, in order to avoid structural damages, water cooled panels are used in order to maintain the temperature of the structure below the failing point.

Tipically, an electric arc furnace has several cooling systems. Normally, those systems comprise a cooling liquid recirculation circuit passing through all the elements of the furnace exposed to high temperatures. The water circulating inside the circuits, passes through the elements that need to be cooled such as Shell & Roof panels, gas exhaust Ducts, etc., in order to remove heat from those elements and subsequently transfer that heat to the environment using a cooling tower or an equivalent device.

The cooling circuit is typically comprised by several feeding pumps, return pumps, filters, one or more cooling towers as well as supervision and control instruments. The key elements of the furnace normally have instruments to monitor the flow, pressure and temperature of the water.

For most water cooled equipment, a flow interruption or an inadequate volume of water circulating through the cooling system may cause a serious thermal overload and sometimes a catastrophic failure.

Current electric arc furnaces have a variable quantity of water cooled panels mounted on a support frame, which allows for quick individual replacement of each panel. By cooling the furnace structure, thermal expansion and thermal stress are avoided which may cause gaps between panels. Water cooled panels allow the furnace to withstand high temperatures without suffering any structural damage. In old design electric arc furnaces, such high temperatures may have caused a higher erosion rate of the refractory walls and damages to the furnace shell.

Furthermore, cooling coils are used in the gas exhaust Ducts in order to cool said Ducts and avoid a structural damage and to cool down the gases to an adequate temperature for the filters to which the gases are conducted.

Typically the water cooled panels have a tubular design and comprise a hydraulic circuit requiring more than one pipe. In order to conduct the water from one pipe to the next one in the circuit, 90° & 180° elbows are used. This kind of hydraulic circuit is normally called “coil”.

The use of said 180° elbows allows for a gap between the pipes that ranges from 0 to approximately a distance equivalent to the diameter of the pipe. Said 180° elbows are formed (cast, forged) independently of the pipes and are welded to the end of each pipe.

The process of welding an elbow to the ends of the pipes is costly, time consuming and creates a potential failure point.

Furthermore, the internal welded seams may cause additional pressure losses when the coil is in operation, reducing the efficiency of the entire cooling system.

In view of the above referred problems, the applicant developed a novel water cooled panel comprised by a continuous coil which lacks welded 180° elbows since they are integrally formed with the pipe.

The water pressure losses obtained with the novel coil are equal or lower than the pressure losses obtained with the coils having welded elbows, thus optimizing the amount of electric energy used by the pumps which circulate the water through the cooling system.

SUMMARY OF THE INVENTION

It is therefore a main object of the present invention to provide a water cooled panel comprised by a continuous coil lacking welded 180° elbows since the return sections are integral part of the pipe.

It is an additional object of the present invention to provide a water cooled panel comprised by a continuous coil in which the water pressure losses are equal or less than the pressure losses obtained with coils using welded elbows, thus optimizing the amount of electric energy used by the pumps which circulate the water through the cooling system.

These and other objects and advantages of the present invention will become apparent to those persons having an ordinary skill in the art, from the following detailed description of the embodiments of the invention, which will be made with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS.

FIG. 1 is a front view of a section of the water cooled panel of the present invention.

FIG. 2 is a graph showing the pressure losses of a coil fabricated with 2½″ schedule 80 pipe using 180° welded elbows versus the pressure losses of a coil fabricated with 2½″ schedule 80 pipe with 180° elbows in accordance with the present invention.

FIG. 3 is a graph showing the pressure losses of a coil fabricated with 2½″ schedule 160 pipe using welded elbows versus the pressure losses of a coil formed with 2½″ schedule 160 pipe with 180° elbows in accordance with the present invention.

DETAILED DESCRIPTION OF THE INVENTION

The invention will now be described making reference to a preferred method for its manufacture and to specific examples of use by which the advantages of the water cooled panel comprised by a continuous coil of the present invention will be clearly appreciated when comparing the numeric values of pressure looses obtained versus a normal pipe.

The water cooled panel comprised by a continuous coil of the present invention may be manufactured by the method described in U.S. patent application Ser. No. 10/769,904, wherein said process comprising the steps of:

Providing a pipe made of a metallic material selected form the group consisting of: carbon steel, copper and its alloys, stainless steel, low alloy steel, aluminum, etc. and of the type selected from the group consisting of: conventional or seamless, extruded, ribbed (splined), within a thickness ranging from schedule 40 to schedule XXS;

defining a tangency point where a bend will occur;

pre-heating the pipe by means of the flame of an oxi-gas torch at the tangency point plus approximately 2″ at a temperature of between 570° F. to 2200° F. for a time of between 30 seconds to 60 minutes and at a distance between the torch tip and the pipe that depends on the pipe material and thickness. An adequate pre-heating allows the material to yield when carrying out subsequent bending steps, minimizing deformations;

pre-bending the pipe 180° using as reference the tangency point as bending point in order to obtain a “U” shaped piece having two straight sections depending of a bent section, using conventional means which may comprise any bending tool, until a bending radius R/D of 1 to 3 is obtained wherein R=bending radius and D=external pipe diameter;

heating the bent section in a special gas or induction furnace at a temperature of between 570° F. to 2200° F. and for a time of between 1 to 60 minutes depending on the pipe material and thickness;

immediately after removing the bent section from the furnace, introducing it to a special press having two lateral pressure elements, each applying a lateral pushing force along a straight section respectively for a distance of approximately 12″ from the bent section, and a pressure element which applies a pushing force on the tangency point perpendicular to the lateral pushing forces, in order to provide to the “U” shaped piece the required final bending radius. As a result of this step, the cross sections of the straight and bent section acquire an oval shape;

applying a vertical compression force to the entire “U” shaped piece in order to round the straight and bent sections until the required roundness is obtained, by means of a press including a mold having the shape of the “U” shaped piece with the required roundness;

repeat the above described steps until forming all the required return sections of a coil.

If the pipe to be processed is made out of alloy steel, then a thermal treatment after the last step of the process is required. If the pipe to be processed is made of stainless steel, then a solution thermal treatment is necessary after the last step of the process.

It should be noted that the water cooled panel comprised by a continuous coil of the present invention may be manufactured by any other method capable of producing a bending radius R/D within a range of 0.5 to 3.

The water cooled panel of the present invention such as the one shown in FIG. 1 is comprised by a continuous coil having a plurality of straight pipe sections 1 and “U” shaped 180° elbow sections 2 that are integral part of the pipe.

Furthermore, the water cooled panel of the present invention may include continuous 90° elbow sections 3.

The water cooled panel comprised by a continuous coil of the present invention may be formed by a pipe having a wall thickness ranging from schedule 40 to XXS.

As it has been demonstrated by the above referred examples of use and its numerical results, the water cooled panel comprised by a continuous coil of the present invention has the advantage of achieving lower or equal pressure losses in comparison with the coils having welded 180° elbows as shown in the following examples:

EXAMPLE 1

A coil was formed having the following characteristics:

-   -   Pipe material: A106-Gr B     -   Pipe dimensions: 2½″ ø, Sch. 80     -   Number of 180° elbow sections: 9     -   Pipe lenght (without 180° elbow sections): 32 ft.     -   Water cooled area: 8.7 ft²         Results:

-   Bending radius: 0.5 D (separation between straight sections 0.0 in)

Pressure losses: lower than the pressure losses of a coil having the same size but using welded elbows, as shown in Table 1 and the graph of FIG. 2, wherein: Ex shows the “X” axis representing a flow scale in gallons per minute (gpm); Ey shows the “Y” axis representing pressure losses scale in psi; 1 represents the pressure losses curve produced by a coil using welded elbows; and 2 represent the pressure losses curve obtained by the coil in accordance with the present invention. TABLE 1 PRESSURE LOSSES COMPARISON CHART FOR SCH. 80 PIPE. COIL USING WELDED 180° ELBOWS VS COIL FORMED BY THE PROCESS OF THE PRESENT INVENTION PRESSURE LOSSES (PSI) FLOW WITH WELDED 180° DIFERENCE (GPM) BENT PIPE ELBOWS % 0 0 0 0.0000 10 0.06001624 0.08084368 25.7626 20 0.23162623 0.31493599 26.4529 30 0.51099019 0.69843715 26.8381 40 0.89629347 1.22953250 27.1029 50 1.38634242 1.90702840 27.3035 60 1.98025490 2.73004272 27.4643 70 2.68185495 3.70239948 27.5644 80 3.50283095 4.83578707 27.5644 90 4.43327043 6.12029301 27.5644 100 5.47317337 7.55591730 27.5644 110 6.62253977 9.14265994 27.5644 120 7.88136965 10.88052090 27.5644 130 9.24966299 12.76950020 27.5644 140 10.72741980 14.80959790 27.5644 150 12.31464010 17.00081390 27.5644 160 14.01132380 19.34314830 27.5644

EXAMPLE 2

A coil was formed having the following characteristics:

-   -   Pipe material: A106-Gr B     -   Pipe dimensions: 2½″ Ø, Sch. 160     -   Number of 180° elbow sections: 9     -   Pipe length (without 180° elbow sections): 32 ft.         -   Water cooled area: 8.7 ft²             Results:

-   Bending radius: 0.5 D (separation between straight sections 0.0 in)

Pressure losses: lower than the pressure losses of a coil with the same size but using welded 180° elbows, as shown in Table 2 and FIG. 3 graph, wherein: Ex shows the “X” axis representing a flow scale in gallons per minute (gpm); Ey shows the “Y” axis representing a pressure loss scale in psi; 1 represents the pressure loss curve produced by a coil using welded 180° elbows; and 2 represents the pressure loss curve obtained by the coil of the present invention. TABLE 2 PRESSURE LOSSES COMPARISON FOR SCH. 160 COIL USING WELDED 180° ELBOWS VS COIL FORMED BY THE PROCESS OF THE PRESENT INVENTION PRESSURE LOSS (PSI) FLOW WITH WELDED 180° DIFFERENCE (GPM) BENT PIPE ELBOWS % 0 0 0 0.0000 10 0.06991225 0.10453932 33.1235 20 0.26587133 0.40437959 34.2520 30 0.58160812 0.89325170 34.8887 40 1.01415987 1.56819290 35.3294 50 1.56157775 2.42725436 35.6648 60 2.21866089 3.46523521 35.9737 70 3.01984399 4.71657015 35.9737 80 3.94428603 6.16041816 35.9737 90 4.99198701 7.79677923 35.9737 100 6.16294692 9.62565337 35.9737 110 7.45716578 11.64704060 35.9737 120 8.87464357 13.86094090 35.9737 130 10.41538030 16.26735420 35.9737 140 12.07937600 18.86628060 35.9737 150 13.86663060 21.65772010 35.9737 160 15.77714410 24.64167260 35.9737 

1. A tubular cooling element comprising a continuous coil having one or more straight pipe sections and one or more “U” shaped elbow sections bent at 180° that are integral part of the pipe, said tubular cooling element comprised by a pipe having a wall thickness ranging from schedule 40 to XXS.
 2. A tubular cooling element as claimed in claim 1, wherein the bending radius R/D of the elbows bent at 180° is within a range of 0.5 to
 3. 3. A tubular cooling element as claimed in claim 1, further including continuous sections bent at 90°. 